Frequency and time slot synchronizaton using adaptive filtering
First Claim
1. A method for frequency synchronization between a cellular communication base station that transmits a plurality of signals, at least one of the plurality of signals having a frequency correction tone, and a mobile communication device that receives the plurality of signals, each of the plurality of signals having a carrier frequency, the mobile communication device having local oscillating means with a variable frequency, the method comprising the steps of:
- filtering an input signal of the plurality of signals to produce a first filtered signal;
buffering the input signal to produce a buffered signal;
determining if the frequency correction tone is present in the input signal by determining an energy of the input signal and an energy of the first filtered signal and a duration for which a relationship between these energies exists;
when the frequency correction tone is present, filtering the buffered signal to produce a second filtered signal; and
when the frequency correction tone is present, determining from the second filtered signal a frequency difference between the carrier frequency of the input signal and a frequency of the local oscillating means.
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Accused Products
Abstract
The synchronization process of the present invention filters the received signal with an adaptive band-pass filter (101) while buffering the received signal in memory (108). The energies of the input signal and the filtered signal are estimated (103 and 104) and the gain of the filter is adapted (105) based on the difference between the energies. The pole of the filter is adapted (102) to center the frequency of the input signal in the filter'"'"'s pass-band. If a tone is detected (106), the length of the tone is determined (107) to ascertain if it is a frequency correction burst (FCB). If the tone detected is an FCB, the signal in the memory is also the FCB that is then filtered in the band-pass filter (101) and the difference between the frequency of this signal and 67.5 kHz is determined (109). This difference represents the frequency offset between the base station carrier frequency and that of the mobile radiotelephone, and can be fed into the local oscillating means to compensate for the frequency offset. The boundaries of the FCB establish the time slot alignment of the TDMA structure being received from the base station.
49 Citations
7 Claims
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1. A method for frequency synchronization between a cellular communication base station that transmits a plurality of signals, at least one of the plurality of signals having a frequency correction tone, and a mobile communication device that receives the plurality of signals, each of the plurality of signals having a carrier frequency, the mobile communication device having local oscillating means with a variable frequency, the method comprising the steps of:
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filtering an input signal of the plurality of signals to produce a first filtered signal; buffering the input signal to produce a buffered signal; determining if the frequency correction tone is present in the input signal by determining an energy of the input signal and an energy of the first filtered signal and a duration for which a relationship between these energies exists; when the frequency correction tone is present, filtering the buffered signal to produce a second filtered signal; and when the frequency correction tone is present, determining from the second filtered signal a frequency difference between the carrier frequency of the input signal and a frequency of the local oscillating means. - View Dependent Claims (2, 3)
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4. A method for frequency synchronization in a time division multiple access (TDMA) cellular communication system between a communication base station that transmits a plurality of TDMA signals at a plurality of frequencies, and a mobile communication device that receives the plurality of signals, each signal having a carrier frequency and is comprised of a plurality of samples and at least one of the signals having a frequency correction tone, the mobile communication device having local oscillating means with a variable frequency that varies in response to the frequency correction tone, the method comprising the steps of:
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filtering a first signal of the plurality of signals with an adaptive filter to produce a filtered signal, the adaptive filter having a variable gain and a variable pole; buffering the first signal to produce a buffered signal; determining a first energy level of the first signal; determining a second energy level of the filtered signal; varying the gain of the adaptive filter in response to a difference between the first and second energy levels; varying the pole of the adaptive filter in response to a frequency of a second signal; when the first energy level is equal to the second energy level, determining a quantity of samples of the first signal for 7hich a relationship between the first and the second energies exists; when the quantity of samples is substantially a predetermined number, filtering the buffered signal to produce a second filtered signal; and if the quantity of samples is substantially the predetermined number, determining from the second filtered signal a frequency difference between the carrier frequency of the first signal and a frequency of the local oscillating means. - View Dependent Claims (5)
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6. A radiotelephone for use in a TDMA type cellular communication system, the radiotelephone having demodulation means for generating I and Q signals, the radiotelephone comprising:
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a) means for transmitting a signal; b) means for receiving a plurality of signals, coupled to the demodulation means, the demodulation means processing the plurality of signals to generate the I and Q signals; and c) processing means for processing the I or Q signals, the processing means performing the steps of; filtering a first signal of the plurality of signals with an adaptive filter to produce a first filtered signal; buffering the first signal to produce a buffered signal; determining if the frequency correction tone is present in the first signal by determining an energy of the first signal and an energy of the first filtered signal and a duration for which a relationship between these energies exists; when the frequency correction tone is present, filtering the buffered signal to produce a second filtered signal containing carrier frequency offset information; and when the frequency correction tone is present, determining from the second filtered signal a frequency difference between a carrier frequency of the first signal from a base station and a frequency of a local oscillating means of the radiotelephone.
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7. A radiotelephone for use in a TDMA type communication system, the radiotelephone having demodulation means for generating I and Q signals from received signals, the radiotelephone comprising:
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means for transmitting signals; means for receiving signals, each signal having a carrier frequency, the means for receiving signals coupled to the demodulation means; local oscillating means having a frequency that varies in response to a frequency difference; and processing means for processing the I or Q signals, the processing means performing a method comprising the steps of; filtering a first signal of the received signals to produce a first filtered signal; buffering the first signal to produce a buffered signal; determining if the frequency correction tone is present in the first signal by determining an energy of the first signal and an energy of the first filtered signal and a duration for which a relationship between these energies exists; when the frequency correction tone is present, filtering the buffered signal to produce a second filtered signal; and when the frequency correction tone is present, determining from the second filtered signal the frequency difference between the carrier frequency of the first signal and a frequency of the local oscillating means.
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Specification